Amorphous ice is less dense than crystalline, why?

In summary: The article mentions LDA and HDA. What are they?LDA is the low-density ice and HDA is the high-density ice.
  • #1
Mk
2,043
4
http://www.lsbu.ac.uk/water/amorph.html puts the densities of various forms of amorphous ice at densities that are very low. g/cm-3 in fact. Is this a typographical error? If not why is it so dense? Crystalline ice's densities are attributed to all the empty space in-between crystals, amorphous ices have much less empty space.
 
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  • #2
Mk said:
amorphous ices have much less empty space.

And this is based on what?
 
  • #3
Hi Mk,

Imagine you have to fill a given box with small rigid cubes. Firstly you trow (fast and randomly) the cubes in the box and secondly you arrange them one by one.
 
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  • #4
Which one is the amorphous and crystalline? I'm assuming the first is amorphous, that's why its dess dense?
 
  • #5
According to the article, there's LDA and HDA. Which are you asking about ?
 
  • #6
Mk said:
http://www.lsbu.ac.uk/water/amorph.html puts the densities of various forms of amorphous ice at densities that are very low. g/cm-3 in fact. Is this a typographical error? If not why is it so dense? Crystalline ice's densities are attributed to all the empty space in-between crystals, amorphous ices have much less empty space.

So amorphous is a bit more dense than crystalline, if remember its density about right ... the differences are of the order of some tens or percents depending on what forms of ice in question ... doesn't appear a typo to me.
 
  • #7
I would have thought that amorphous (having no crystalline structure) has a larger opportunity for trapping air, whereas crystalline being geometric contains a fixed amount.

ie, the crystalline ice traps air between the intermolecular (H) bonds, and as such has a fixed density, while amorphous ice has a random element (in molecular alignment) leaving extraneous spaces between said molecules.

The analogy above is intuitive - being a random pile (amorphous) allows more gaps so more air and thus less density, compared to a stack with no gaps (crystal)...
 
  • #8
But then, you can also compress amorphous ice and find stable configurations that lie on the other side of an energy barrier, enabling a higher final density.
 
  • #9
True, but that doesn't exclude the possibility of amorphous ice having a lower density up until it is compressed. :D

How much can crystalline ice be compressed before it loses its structure?
 
  • #10
This issue is best dealt with from the standpoint of engineering or chemistry. The issue is one of crystal structure and what, exactly, different structures look like. http://www.chem.lsu.edu/htdocs/people/sfwatkins/ch4570/lattices/lattice.html" is another site showing packing factors of various crystals. It is important to note that the packing factor is the same for all materials. It is the geometric relationship between the number of particles and the volume.

Amorphous is tougher than crystalline because the density can vary, but as a general rule, ordered packing is more efficient than disordered, thus crystalline is always (afaik) more efficiently packed than amorphous. The reason has been said above: in amorphous, you get semi-random arrangements that often cause large voids.
 
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1. Why is amorphous ice less dense than crystalline ice?

Amorphous ice has a disordered molecular structure, while crystalline ice has a regular, repeating pattern of molecules. This results in a less compact arrangement in amorphous ice, leading to a lower density.

2. Does this mean that amorphous ice is weaker than crystalline ice?

No, the strength of ice is determined by the strength of its hydrogen bonds, which are not affected by the density. Therefore, amorphous ice can still be just as strong as crystalline ice despite its lower density.

3. Can amorphous ice form naturally?

Yes, amorphous ice can form naturally under certain conditions such as rapid cooling or high pressure. It can also be artificially produced in laboratories through techniques such as vapor deposition.

4. How does the density of amorphous ice affect its properties?

The lower density of amorphous ice can affect its properties in various ways. For example, it may have a higher porosity, making it more permeable to gases and liquids. This can also affect its thermal and electrical conductivity.

5. Are there any practical applications for amorphous ice?

Yes, amorphous ice has been studied for its potential use in cryopreservation, as it is less likely to damage cells due to its lower density. It is also being explored for use in energy storage and as a catalyst in chemical reactions.

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